show/hide this revision's text 5 added 147 characters in body

There is a slight flaw in ghoseb's solution, making it O(n**2), rather than O(n).
The problem is that this is performing:

item = l1.pop(0)

With linked lists or deques this would be an O(1) operation, so wouldn't affect complexity, but since python lists are implemented as vectors, this copies the rest of the elements of l1 one space left, an O(n) operation. Since this is done each pass through the list, it turns an O(n) algorithm into an O(nO(n**2) one. This can be corrected by using a method that doesn't alter the source lists, but just keeps track of the current position.

I've tried out benchmarking a corrected algorithm vs a simple sorted(l1+l2) as suggested by dbr

def merge(l1,l2):
    if not l1:  return list(l2)
    if not l2:  return list(l1)

    # l2 will contain last element.
    if l1[-1] > l2[-1]:
        l1,l2 = l2,l1

    it = iter(l2)
    y = it.next()
    result = []

    for x in l1:
        while y < x:
            result.append(y)
            y = it.next()
        result.append(x)
    result.append(y)
    result.extend(it)
    return result

I've tested these with lists generated with

l1 = sorted([random.random() for i in range(NITEMS)])
l2 = sorted([random.random() for i in range(NITEMS)])

For various sizes of list, I get the following timings (repeating 100 times):

# items:  1000   10000 100000 1000000
merge  :  0.079  0.798 9.763  109.044 
sort   :  0.020  0.217 5.948  106.882

So in fact, it looks like dbr is right, just using sorted() is preferable unless you're expecting very large lists, though it does have worse algorithmic complexity. The break even point being at around a million items in each source list (2 million total).

One advantage of the merge approach though is that it is trivial to rewrite as a generator, which will use substantially less memory (no need for an intermediate list).

[Edit] I've retried this with a situation closer to the question - using a list of objects containing a field "date" which is a datetime object. The above algorithm was changed to compare against .date instead, and the sort method was changed to:

return sorted(l1 + l2, key=operator.attrgetter('date'))

This does change things a bit. The key function comparison being more expensive means that the number of comparisons we perform becomes more important, so relative to the constant-time speed of the implementation. This means merge makes up lost ground, surpassing the sort() method at 100,000 items instead. merge methodComparing based on an even more complex object (large strings or lists for instance) would likely shift this balance even more.

# items:  1000   10000 100000  1000000[1]
merge  :  0.161  2.034 23.370  253.68
sort   :  0.111  1.523 25.223  313.20

[1]: Note: I actually only did 10 repeats for 1,000,000 items and scaled up accordingly as it was pretty slow. Shouldn't make much difference.
show/hide this revision's text 4 Add timing figures for using objects with datetime fields.

There is a slight flaw in ghoseb's solution, making it O(n**2), rather than O(n).
The problem is that this is performing:

item = l1.pop(0)

With linked lists or deques this would be an O(1) operation, so wouldn't affect complexity, but since python lists are implemented as vectors, this copies the rest of the elements of l1 one space left, an O(n) operation. Since this is done each pass through the list, it turns an O(n) algorithm into an O(n) one. This can be corrected by using a method that doesn't alter the source lists, but just keeps track of the current position.

I've tried out benchmarking a corrected algorithm vs a simple sorted(l1+l2) as suggested by dbr

def merge(l1,l2):
    if not l1:  return list(l2)
    if not l2:  return list(l1)

    # l2 will contain last element.
    if l1[-1] > l2[-1]:
        l1,l2 = l2,l1

    it = iter(l2)
    y = it.next()
    result = []

    for x in l1:
        while y < x:
            result.append(y)
            y = it.next()
        result.append(x)
    result.append(y)
    result.extend(it)
    return result

I've tested these with lists generated with

l1 = sorted([random.random() for i in range(NITEMS)])
l2 = sorted([random.random() for i in range(NITEMS)])

For various sizes of list, I get the following timings (repeating 100 times):

# items:  1000   10000 100000 1000000
merge  :  0.079  0.798 9.763  109.044 
sort   :  0.020  0.217 5.948  106.882

So in fact, it looks like dbr is right, just using sorted() is preferable unless you're expecting very large lists, though it does have worse algorithmic complexity. The break even point being at around a million items in each source list (2 million total).

One advantage of the merge approach though is that it is trivial to rewrite as a generator, which will use substantially less memory (no need for an intermediate list).

[Edit] I've retried this with a situation closer to the question - using a list of objects containing a field "date" which is a datetime object. The above algorithm was changed to compare against .date instead, and the sort method was changed to:

return sorted(l1 + l2, key=operator.attrgetter('date'))

This does change things a bit. The key function being more expensive means that the number of comparisons becomes more important, so merge makes up lost ground, surpassing the sort() method at 100,000 items instead. merge method

# items:  1000   10000 100000  1000000[1]
merge  :  0.161  2.034 23.370  253.68
sort   :  0.111  1.523 25.223  313.20

[1]: Note: I actually only did 10 repeats for 1,000,000 items and scaled up accordingly as it was pretty slow. Shouldn't make much difference.
show/hide this revision's text 3 Give more details on problem with l.pop()

There is a slight flaw in ghoseb's solution, making it O(n**2), rather than O(n).
The problem is that this is performing:

item = l1.pop(0)

With linked lists or deques this would be an O(1) operation, so wouldn't affect complexity, but since python lists are implemented as vectors, this copies the rest of the elements of l1 one space left, an O(n) operation. Since this is done each pass through the list, it turns an O(n) algorithm into an O(n) one. This can be corrected by using a method that doesn't alter the source lists, but just keeps track of the current position.

I've tried out benchmarking a corrected algorithm vs a simple sorted(l1+l2) as suggested by dbr

def merge(l1,l2):
    if not l1:  return list(l2)
    if not l2:  return list(l1)

    # l2 will contain last element.
    if l1[-1] > l2[-1]:
        l1,l2 = l2,l1

    it = iter(l2)
    y = it.next()
    result = []

    for x in l1:
        while y < x:
            result.append(y)
            y = it.next()
        result.append(x)
    result.append(y)
    result.extend(it)
    return result

I've tested these with lists generated with

l1 = sorted([random.random() for i in range(NITEMS)])
l2 = sorted([random.random() for i in range(NITEMS)])

For various sizes of list, I get the following timings (repeating 100 times):

# items:  1000   10000 100000 1000000
merge  :  0.079  0.798 9.763  109.044 
sort   :  0.020  0.217 5.948  106.882

So in fact, it looks like dbr is right, just using sorted() is preferable unless you're expecting very large lists, though it does have worse algorithmic complexity. The break even point being at around a million items in each source list (2 million total).

One advantage of the merge approach though is that it is trivial to rewrite as a generator, which will use substantially less memory (no need for an intermediate list).
show/hide this revision's text 2 Added missing append of y
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